A flat-shaped composite material is represented and described for manufacturing a package, including: a polymer outer layer, a polymer inner layer, a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. The flat-shaped composite material has a plurality of fold lines, which are arranged and designed such that a closed package can be manufactured by folding the flat-shaped composite material along the fold lines and by connecting seam surfaces of the flat-shaped composite material and a sleeve surface. The sleeve surface includes a front surface, a first side surface, a second side surface, a first rear surface and a second rear surface, and base surfaces. The base surfaces include triangular base surfaces and quadrangular base surfaces and gable surfaces. The gable surfaces include triangular gable surfaces and quadrangular gable surfaces. The base surfaces and the gable surfaces are arranged on opposite sides of the sleeve surface. In order to enable the manufacture of packages with even more complex geometries even in the gable and base region, at least one quadrangular gable surface is provided with two small gable surface angles, which are smaller than 90°, with two large gable surface angles, which are greater than 90°, and with an angle sum, which is greater than 360°. A package sleeve made of a composite material and a package manufactured from the composite material or from the package sleeve are also represented and described.

Various forms of tabbed sealing members are described along with the laminates from which the sealing members are formed. In some forms, the tabbed sealing members may be considered inverted tabbed sealing members for induction sealing as the induction heating layer is provided in the upper laminate instead of the lower laminate. In this regard, the induction heating layer is positioned further from the heat seal, contrary to conventional tabbed sealing members.

A single ply napkin food wrapper is moisture resistant on the food side but moisture absorbent on the outside. The wrapper is used to wrap food when delivered to the customer and the wrapper can later be used as a napkin by the customer. Delivery of a napkin is thus ensured with each food item.

A single ply napkin food wrapper is moisture resistant on the food side but moisture absorbent on the outside. The wrapper is used to wrap food when delivered to the customer and the wrapper can later be used as a napkin by the customer. Delivery of a napkin is thus ensured with each food item.

The thermal transfer image-receiving sheet according to the present disclosure includes a receiving layer, a front substrate, a porous layer, and a rear substrate in this order and further includes a metal-containing layer interposed between the receiving layer and the front substrate or between the front substrate and the porous layer. The thermal conductivity of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 0.38 W/m.Math.K or less. The Martens hardness of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 10.0 N/mm.sup.2 or less. The 45-degree specular gloss of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 800 or more.

The thermal transfer image-receiving sheet according to the present disclosure includes a receiving layer, a front substrate, a porous layer, and a rear substrate in this order and further includes a metal-containing layer interposed between the receiving layer and the front substrate or between the front substrate and the porous layer. The thermal conductivity of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 0.38 W/m.Math.K or less. The Martens hardness of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 10.0 N/mm.sup.2 or less. The 45-degree specular gloss of the thermal transfer image-receiving sheet which is measured on the receiving layer-side is 800 or more.

An improved paperboard pouch comprising a multilayer substrate and a method of making the same is provided. The multilayer paperboard pouch comprises an outer surface and an inner surface, wherein one of the surfaces is defined as a food contact surface. In the depicted embodiment, the properties of the polymer layer are chosen to provide adequate mechanical and barrier protection to the paper-based pouch formed on the conventional pouch-forming equipment. A method of manufacturing a multilayer paperboard pouch using conventional bag-making equipment (“CBME”) running at normal production speed for making standard plastic pouches is also provided. First, a paper is extrusion-coated and then the CBME is configured with a feeder for feeding an extrusion-coated paper intermittently for a length along a feeding path; a cutter disposed at a position predetermined for cutting one of the layers of the coated paper and forming a first side gusset, a second side gusset and a bottom gusset portions and for folding each of a first side gusset, a second side gusset and a bottom gusset portions into halves along a center line extending longitudinally thereof; and a sealer for sealing the layers of the polymer with the layers of the bottom gusset portion and the layers of the first and second gusset portions, respectively to form the finished multilayer paperboard pouch ready for sale and distribution to various retailers. It is to be noted that in the depicted embodiment various closure constructions and mechanism can be used for heat sealing the finished pouches.

A recyclable corrugated board can include a first outer layer, a second outer layer, and a non-wicking medium attached to and disposed between the first outer layer and the second outer layer. The non-wicking medium is not impregnated and is not coated. The non-wicking medium can be corrugated paper, for example.

The present invention relates to an adsorbent suitable for the adsorption of MOAH and/or MOSH compounds, the use of the adsorbent for the production of a packaging material or a container comprising the adsorbent, the process of production of the packaging material or container as well as the respective packaging material and container.

A packaging container (1, 201) comprising a container body (2, 202) having a bottom end (4, 204) and a top end (5, 205) and a tubular container wall (3, 203) extending between the bottom end and the top end. The packaging container(1, 201) is closed at the bottom end (4, 204) by a base disc (9, 209) which is attached by welding to the inner surface (7, 207) of the container body (2, 202) at the bottom end (4, 204) of the container body. The container body comprises a laminate body sheet material (12) comprising a carton layer (12a), a metallic foil layer (12b) and an inner thermoplastic polymeric layer (12c). A top end closure comprising an openable and reclosable lid (16, 216) is arranged at the top end of the packaging container (1). The top end closure comprises an openable inner sealing member (33, 233) which is attached by welding to the inner surface (7, 207) of the container body (2, 202) at a distance from the top end (5, 205) of the container body (2, 202), the inner sealing member (33, 233) comprising a first laminate sealing member sheet material (244′) comprising a structural layer (244a) and a thermoplastic welding layer (244b) and a second laminate sealing member sheet material (244″) comprising a metallic foil layer (244a″) and a thermoplastic welding layer (244″b), the second laminate sealing member sheet material (244″) being joined to the first laminate sealing member sheet material (244′) by welding. The structural layer (244a) of the first laminate sealing member sheet material (244) is a metallic foil layer having a thickness of from 5 micrometer to 10 micrometer, such as from 5.5 micrometer to 9 micrometer.